DE2153630B2 - Transmit-receive aerial reversing circuit - uses inverter delay chains to control aerial and supply relays - Google Patents

Abstract

The reversing circuit controls a change-over relay connected to a transmit/receive aerail and has a delay circuit to delay the relay such that the aerial relay operates before the relay that connects in the d.c. supply voltage when changing over from receive to transmit. The supply relay operates before the aerial relay when changing over from transmit to receive. The delay circuit consists of several inverters forming two chains each with RC components. The first chain is assigned to the supply relay (G) and the second chain to the aerial relay (A). The charging time of the RC capacitors is much greater than their discharging time.

Description

The invention relates to a circuit arrangement for switching the transmission direction in a Transmitter and a receiver by means of an antenna relay switching the antenna, one the DC supply voltage or a control stage switching feed relay and a delay device, which these Relay delayed so that after switching from »Receive« to »Send« only the antenna relay and then the feed relay and after switching from »send« to »receive« first the feed relay and then the antenna relay can be actuated.

Such a circuit arrangement is known from German Offenlegungsschrift 19 54 449. at In this known circuit arrangement, the antenna can optionally be switched to the antenna Transmitter or the antenna input of the receiver switching antenna relay with one winding and on the DC supply voltage to either a supply voltage input of the transmitter or a supply voltage input of the receiver switching feeder relay with two windings used By a control switch is the supply voltage of the first winding of the feed relay and the series connection from the second winding of the feed relay and a capacitor and also the winding of the Antenna relay can be fed in via a diode, the antenna relay being connected to the via a further diode Capacitor is coupled. The antenna relay responds when the control switch is closed. Simultaneously the feed relay is excited via its first winding and with the charging current of the capacitor its second winding counter-excited, so that it is delayed for about the duration of the capacitor charging process appeals to. When the control switch is opened, the feed relay drops out, while the antenna relay drops out the discharge current of the capacitor flowing through the further diode and the antenna relay is delayed falls off. This mutual delay of the relay ensures that the transmitter never goes without Antenna load is running and the transmitter output stage is thus protected against destruction. This well-known Circuit arrangement has the disadvantages that the feed relay must be equipped with two windings and therefore no uniform feed and antenna relays can be used and that the control contact is heavily loaded by the current through three relay windings.

Another circuit arrangement of the type mentioned is known in which the transmitter and the Receivers have a common antenna connection and an antenna connection to this Transmission line amplifier can be switched on, which can be switched on on the output side to the Αηίεηηε. This im Transmission state of the transmitter effective transmission power amplifier is in the reception state of the transmitter and Bypassed recipient. This is done by means of an antenna relay and a feed relay, which the Release the transmission line amplifier on the output and input side and remove the antenna from the transmission amplifier output switch to the common antenna connection. So here too the transmission power amplifier output stage never runs without antenna load, these relays are delayed by means of a delay device so delayed that after switching from »receive« to »transmit« the antenna relay and then the high-frequency voltage at the input of the transmission power amplifier and the feed relay After switching from »Send« to »Receive«, first the feed relay and then the antenna relay be operated. These relays are delayed accordingly by sounding with capacitors. The delay device has approximately the same disadvantages as the first-mentioned known arrangement.

By the German Offenlegungsschrift 15 37 989 is also known a delay circuit for delaying square-wave pulses consisting of three in series connected inverters and one each parallel to the control path of the second and third inverter switched capacitor. The second capacitor in this inverter chain delays the Leading edge of the square pulse during the first capacitor for delaying the trailing edge of the

The object of the invention is to provide a circuit arrangement of the type mentioned at the beginning indicate in which the disadvantages of the first two known circuit arrangements are exploited are prevented by features of the last-mentioned known circuit arrangement. This is done according to the invention achieved in that the delay device with an integrated module several inverters is formed that from these inverters by series connection two known, provided with ÄC elements and the relays individually Upstream chains are designed so that the chain associated with the feed relay has at least one Has an inverter, connected to the output of an ÄC element which determines the response time of the feed relay is that the chain associated with the antenna relay has at least two inverters, with the The output of the second inverter is connected to a C-link that determines the fall time of the antenna relay is that each /? C element is dimensioned so that the charging time copant for its capacitor is much greater than the Discharge time constant, and that the two chains are controlled in parallel.

An expedient design is characterized in that the chain upstream of the feed relay and the chain upstream of the antenna relay are formed from four inverters and that an RC-GMed between the two inverters of the chain upstream of the feeder relay and another RC-CWed between the second and third inverters of the other chain are arranged. By dividing the inverters of an integrated module in this way, the two inputs of the inverter chains can simply be connected together and controlled by one and the same plug-in contact: the outputs of the chains can also be easily interconnected via the relays.

In order to be able to use the delay device universally, according to a further embodiment of the Invention an integrated module with open -to working electrodes of the inverting amplifier elements selected; the working electrodes are in this case changeable via individual discrete resistors Tap of the supply voltage source connected. This means that freely selectable time constants can be achieved and also the delay times depending on the specified transmitter powers by changing them Supply voltage for the delay device can be set.

The invention will now be explained in more detail using an exemplary embodiment. It shows

Fig. 1 shows a receiver and a transmitter for two-way communication with the switch for the Antenna and the switch for the DC voltage supply of the receiver and the transmitter,

2 shows a receiver, a transmitter and a transmission power amplifier for alternating mirror traffic with the switch for the antenna and the switch at the input of the transmission power amplifier,

3 shows a circuit arrangement for delay ω the changeover contacts in FIG. 1 actuating relay,

F i g. 4 is a relay diagram for the one shown in FIG. 2 shown antenna relays and the feed relay and

F i g. 5 is a graph in which the delay time as a function of the capacitance of the delay capacitor is shown as a parameter for different supply voltages for the inverter.

in Fig. 1 isi a receiver E connected to an antenna AN via the rest of the switching contact a, while the antenna input of a transmitter S can be connected to the working side of this switching contact. The supply voltage input of the receiver on the fist side of a changeover switch rest gan a pole U connected to a DC supply voltage source, while the supply voltage input of the transmitter S is connectable on the work side of this changeover switch to this pole. The reception status is thus shown. To be switched to the Sendezusiand, so initially the changeover a and only then the changeover # must be operated so that the transmitter output stage is by no means without load. When switching back to the receiving state, the changeover contact g and only then the changeover contact a must first be switched back, because the transmitter has to wait for the transmitter to settle under the initial load.

In Fig. 2 a receiver £ and a transmitter 5 are connected via a common antenna output AG, the rest side of a changeover contact g of a feed relay C and the rest side of a changeover contact a of an antenna relay A with an antenna AN . G on the working side of the changeover switch the input of a Sende'eitungsverstärkers VS from the common antenna output AC is a high frequency control chip pung of the transmitter 5 can be fed, while the output of transmit power amplifier KS on the working side of the changeover contact a to the antenna AN is connected. The reception status is also shown. To be switched to the transmitting state, the changeover a and only then the changeover must be g operated here first, so that the final stage of the power amplifier VS is by no means without load. When switching back to the receiving state, first the changeover contact g and only then the changeover contact u must be switched back because the end stage of the transmission power amplifier VS must be awaited to settle under output load.

In order to achieve such an operating mode of the changeover contacts, according to the invention the one shown in FIG. 3 shown circuit arrangement is provided. Two inverter chains are formed by series connections of inverters / 1 to / 6, which are contained in an integrated module. Such integrated building blocks are small and cheap. In this exemplary embodiment, an integrated module with six inverters has been selected. Of these six inverters, the inverters / 1 and / 2 form the chain provided for the feed relay C , while the inverters / 3 to / 6 form the chain provided for the antenna relay A. Transistors, field effect transistors or similar semiconductor elements can serve as amplifier elements for the inverters. In this exemplary embodiment, an integrated module has been selected in which the working electrodes of the inverter amplifier elements are open. The working electrodes of the amplifier elements in inverters / 1, / 3, / 4 and / 5 receive a variable DC supply voltage Ui via the same resistors IV1 to W4. These resistors can, for example, be connected to a tap of a DC supply voltage source, preferably the direct voltage source U 2, to the tap of a voltage divider connected to the direct voltage source U2 , or to the voltage source U 2 via a controllable series resistor. The voltage Ui can be ir

from 1 to 5 volts, while the voltage Ul can be 24 V, for example. The output of the inverter chain / 1, / 2 is connected via the feed relay G to the DC supply voltage source Ul , to which the output of the second inverter chain / 3 to / 6 is also connected via the antenna relay A. The two inputs of the inverter chains are connected together, biased via a resistor WO and can be connected to earth via a key work contact Γ. Between the inverters / 1 and II of the first chain and the inverters / 4 and / 5 of the second chain there is a capacitor C1 or CI to ground.

The mode of operation of the delay device is as follows: in the state shown, the inverters are the inverters / i. / 3 and / 5 conductive, while the amplifier elements of inverters II, / 4 and / 6 are blocked. Therefore the relays G, A are not energized; the capacitor Cl is short-circuited and the capacitor Cl is charged.

If the key contact T is closed, the switching states of the inverters are reversed. The capacitor C1 is quickly discharged via the conductive switching path of the amplifier element in the inverter / 4, so that the antenna relay A responds almost instantaneously, as shown in the relay diagram according to FIG. When the amplifier element in the inverter / 1 is blocked, the capacitor C1 is charged so that the amplifier element in the inverter II can not become conductive until a later point in time. This means that the feed relay G is switched on with a delay.

If the button contact Two is opened again, the original switching states of the inverters are set again. The capacitor C1 is quickly discharged via the conductive switching of the amplifier element in the inverter / 1, so that the supply relay G drops out almost instantaneously. When locking of the Vcrstärkcrclcmentes in the inverter / 4, the capacitor Cl but is initially loaded so that the Verstärkerelemcnt in the inverter 5 can be controlled to conduct until a later time / Thereby, the drop of the antenna relay A is delayed (see F i g. 3). .

F i g. 5 shows the switching delay of these relays as a function of the capacitance value of the assigned capacitor, the variable voltage LJ I being available as a parameter. It can be seen that the delay time t can only be set over a wide range by changing the DC supply voltage Ui. As a result, the delay time can be adapted to different types of transmitters or power amplifiers with different powers.

The division of the inverters of an integrated module into two inverters for the first chain and four Inverter for the second chain is not mandatory. By using more capacitors on others Inverter outputs can also have a drop-out delay of the feed relay and / or a response delay of the antenna relay can be achieved. For this purpose, for example, it is connected to the output of the inverter / 2 and an additional capacitor is connected to the output of the inverter / 5. It is also

jo possible to use an integrated module without open working electrodes of the amplifier elements in which case, however, the resistance of the time constant can no longer be freely selected.

1 sheet of drawings

Claims (3)

1 claims: 1. Circuit arrangement for switching the transmission direction at a transmitter and a receiver by means of an antenna relay switching the antenna, a supply relay switching the DC supply voltage or a control stage and a delay device which delays these relays in such a way that after switching from "reception" to "transmission" first the antenna relay and then the feed relay and after switching from "send" to "receive" only the feed relay and then the antenna relay are actuated, characterized in that the delay device is formed with an integrated module from several inverters from these inverters by series connection two known, provided with ÄC members and the relays (G. A) individually upstream chains are designed so that the chain associated with the feed relay (C) has at least one inverter (71) at the output of a WC element that determines the response time of the feed relay (Wi, Cl) it is connected that the chain assigned to the antenna relay (A) has at least two inverters (13, / 4), an RC-CWed (Wi, C2) determining the release time of the antenna relay being connected to the output of the second inverter (14) , that each / <C-link is dimensioned in such a way that the charging time constant for its capacitor is much greater than the discharging time constant, and that the two chains are controlled in parallel. 2. Circuit arrangement according to claim 1, characterized in that the chain of two inverters (1 1, 12 ) connected upstream of the Speisereiais (C) and the chain of four inverters (/ 3 to / 4) connected upstream of the antenna relay (A) are formed and that a flC element (W 1, CI) between the two inverters (H, 12) of the chain connected upstream of the feed relay (C) and another RC element (Wi, C2) between the second and third inverter (14, / 5) of the other chain are arranged. 3. Circuit arrangement according to claim 2, characterized in that an integrated module with open working electrodes of the inverter amplifier elements is selected and that the working electrodes are connected via individual discrete resistors (W 1 to W4) to a variable tap (U 1) of the DC supply voltage source. 50